Decomposing demographic contributions to the effective population size with moose as a case study
Lee, Aline Magdalena; Svalheim Markussen, Stine; Engen, Steinar; Solberg, Erling Johan; Haanes, Hallvard; Røed, Knut H.; Herfindal, Ivar; Heim, Morten; Sæther, Bernt-Erik
Peer reviewed, Journal article
Published version
Date
2020Metadata
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Abstract
Levels of random genetic drift are influenced by demographic factors, such as mating system, sex ratio and age structure. The effective population size (Ne) is a useful
measure for quantifying genetic drift. Evaluating relative contributions of different
demographic factors to Ne is therefore important to identify what makes a population vulnerable to loss of genetic variation. Until recently, models for estimating Ne
have required many simplifying assumptions, making them unsuitable for this task.
Here, using data from a small, harvested moose population, we demonstrate the
use of a stochastic demographic framework allowing for fluctuations in both population size and age distribution to estimate and decompose the total demographic
variance and hence the ratio of effective to total population size (Ne/N) into components originating from sex, age, survival and reproduction. We not only show which
components contribute most to Ne/N currently, but also which components have the
greatest potential for changing Ne/N. In this relatively long-lived polygynous system
we show that Ne/N is most sensitive to the demographic variance of older males, and
that both reproductive autocorrelations (i.e., a tendency for the same individuals to
be successful several years in a row) and covariance between survival and reproduction contribute to decreasing Ne/N (increasing genetic drift). These conditions
are common in nature and can be caused by common hunting strategies. Thus, the
framework presented here has great potential to increase our understanding of the
demographic processes that contribute to genetic drift and viability of populations,
and to inform management decisions.